Investigation of Branch Accessibility with a Robotic Pruner for Pruning Apple Trees

IF 1.4 4区 农林科学 Q3 AGRICULTURAL ENGINEERING Transactions of the ASABE Pub Date : 2021-01-01 DOI:10.13031/trans.14132
A. Zahid, Long He, D. Choi, J. Schupp, P. Heinemann
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引用次数: 3

Abstract

HighlightsA branch accessibility simulation was performed for robotic pruning of apple trees.A virtual tree environment was established using a kinematic manipulator model and an obstacle model.Rapidly-exploring random tree (RRT) was combined with smoothing and optimization for improved path planning.Effects on RRT path planning of the approach angle of the end-effector and cutter orientation at the target were studied.Abstract. Robotic pruning is a potential solution to reduce orchard labor and associated costs. Collision-free path planning of the manipulator is essential for successful robotic pruning. This simulation study investigated the collision-free branch accessibility of a six rotational (6R) degrees of freedom (DoF) robotic manipulator with a shear cutter end-effector. A virtual environment with a simplified tall spindle tree canopy was established in MATLAB. An obstacle-avoidance algorithm, rapidly-exploring random tree (RRT), was implemented for establishing collision-free paths to reach the target pruning points. In addition, path smoothing and optimization algorithms were used to reduce the path length and calculate the optimized path. Two series of simulations were conducted: (1) performance and comparison of the RRT algorithm with and without smoothing and optimization, and (2) performance of collision-free path planning considering different approach poses of the end-effector relative to the target branch. The simulations showed that the RRT algorithm successfully avoided obstacles and allowed the manipulator to reach the target point with 23 s average path finding time. The RRT path length was reduced by about 28% with smoothing and by 25% with optimization. The RRT smoothing algorithm generated the shortest path lengths but required about 1 to 3 s of additional computation time. The lowest coefficient of variation and standard deviation values were found for the optimization method, which confirmed the repeatability of the method. Considering the different end-effector approach poses, the simulations suggested that successfully finding a collision-free path was possible for branches with no existing path using the ideal (perpendicular cutter) approach pose. This study provides a foundation for future work on the development of robotic pruning systems. Keywords: Agricultural robotics, Collision-free path, Manipulator, Path planning, Robotic pruning, Virtual tree environment.
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自动修剪机对苹果树枝条可达性的研究
HighlightsA分支可达性仿真对苹果树的自动修剪进行了模拟。利用运动学机械臂模型和障碍物模型建立了虚拟树环境。将快速探索随机树(RRT)与平滑和优化相结合,改进了路径规划。研究了末端执行器进近角和刀具在目标位置对RRT路径规划的影响。机器人修剪是减少果园劳动力和相关成本的潜在解决方案。机械臂的无碰撞路径规划是机器人修剪成功的关键。仿真研究了带剪切刀末端执行器的六自由度(6R)机械臂的无碰撞分支可达性。在MATLAB中建立了一个具有简化高主轴树冠的虚拟环境。采用快速探索随机树(RRT)避障算法,建立到达目标剪枝点的无碰撞路径。此外,利用路径平滑和优化算法减少路径长度并计算出优化后的路径。进行了两个系列的仿真:(1)光滑和优化前后RRT算法的性能和比较;(2)考虑末端执行器相对于目标分支的不同路径位姿的无碰撞路径规划性能。仿真结果表明,RRT算法成功避开障碍物,平均寻径时间为23s,机械手到达目标点。通过平滑和优化,RRT路径长度分别减少了28%和25%。RRT平滑算法产生最短的路径长度,但需要大约1到3秒的额外计算时间。优化方法的变异系数最小,标准差最小,验证了方法的重复性。考虑到不同的末端执行器接近姿态,仿真表明,使用理想(垂直刀具)接近姿态,可以成功地找到没有路径的分支的无碰撞路径。本研究为今后开发机器人修剪系统奠定了基础。关键词:农业机器人,无碰撞路径,机械手,路径规划,机器人修剪,虚拟树环境
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来源期刊
Transactions of the ASABE
Transactions of the ASABE AGRICULTURAL ENGINEERING-
CiteScore
2.30
自引率
0.00%
发文量
0
审稿时长
6 months
期刊介绍: This peer-reviewed journal publishes research that advances the engineering of agricultural, food, and biological systems. Submissions must include original data, analysis or design, or synthesis of existing information; research information for the improvement of education, design, construction, or manufacturing practice; or significant and convincing evidence that confirms and strengthens the findings of others or that revises ideas or challenges accepted theory.
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